Title of Invention

ADAPTIVE RF AMPLIFIER PRELIMITER

Abstract

The invention reduces transient peaks in signals transmitted in COMA communication systems. A plurality of spread spectrum data signals are combined into a combined signal having fluctuating power level corresponding to the combination of the data signals. The combined signal is modulated to produce an RF signal for transmission. The average power of the combined signal is measured over a selected time period. The combined signal power level is adaptively limited to a calculated power level based at least in part on the measured power.

Full Text

Field of the Invention This invention generally relates to spread spectrum code division multiple access (COMA) communication system.. More particularly, the present invention relates to a system and method for adaptively limiting forward and reverse link transmission power within CDMA communication systems. Description of the Prior Art Wireless communication systems using spread spectrum modulation techniques represent the state of the art in digital communications and are increasing in popularity. In code division multiple access (CDMA) system,, data is transmitted using a wide bandwidth (spread spectrum) by modulating the data with a pseudo random chip code sequence. The advantage gained is that CDMA systems are more resistant to signal distortion and interfering frequencies in the transmission channel than communication systems using other multiple access techniques such as time division multiple access (TDMA) or frequency division multiple access (FDMA). One indicator used to measure the performance of a communication system is the signal-to-noise ratio (SNR). At the receive,, the magnitude of the desired received signal is compared to the magnitude of the received noise. The data within a transmitted signal received with a high SNR is readily recovered at the receiver. A low SNR leads to loss of data. A prior art CDMA communication system is shown in Figure 1. The , communication system has a plurality of base stations 201, 202 ... 20N connected together through a local Public Switched Telephone Network (PSTN) exchange. Each base station 201, 202... 20N communicates using spread spectrum CDMA with mobile and fixed subscriber units 221, 222... 22N within its cellular area. Shown in Figure 2 is a simplified COMA transmitter 24 and receiver 26. A data signal having a given bandwidth is mixed with a spreading code generated by a pseudo random chip code sequence generator producing a digital spread spectrum signal for transmission. Upon reception, the data is reproduced after correlation with the same pseudo random chip code sequence used to transmitter the data. By using different pseudo random chip code sequences, many data signals or subchannels can share the same channel bandwidth. In particular, a base station 20, can communicate with a group of subscriber units 221, 222... 22N using the same bandwidth. Forward link communications are from the base station 20, to the subscriber unit 221, 222... 22N, and reverse link communications are from the subscriber unit 221, 222... 22N to the base station 201. For timing synchronization with a receiver 26, an unmodulated pilot signal is used. The pilot signal allows respective receivers 26 to synchronize with a given transmitter 24. allowing despreading of a traffic signal at the receiver 26. In atypical COMA system, each base station 201, 202... 20N sends a unique global pilot signal received by all subscriber units 221, 222 ... 22N within communicating range to synchronize forward link transmissions. Conversely, in some CDMA systems for example in the B-CDMA™ air interface each subscriber unit 221, 222 ... 22N transmits a unique assigned pilot signal to synchronize reverse link transmissions. Figure 3 is an example of a prior art transmitter 24. Data signals 281, 282... 28N including traffic, pilot and maintenance signals arc spread using respective mixers 301, 302... 30N with unique Chip code sequences 321, 322... 32N, respectively. Each mixers' output is coupled to a combiner 34 which adds the individual mixed signals as a combined signal 44. The combined signal 44 is modulated up to radio frequency (RF) by 3 mixer 36 mixing the combined signal 44 with an RF carrier, shown in Figure 3 as COS wt. The modulated signal is amplified to a predetermined transmission power level (TLP) by an amplifier 38 and radiated by an antenna 40. Most CDMA systems use some form of adaptive power control. In a CDMA system, many signals share the same bandwidth. When a subscriber unit 221, 222... 22N or base station 201, 202... 20N is receiving a specific signal, all the other signals within the same bandwidth are noise like in relation to the specific signal. Increasing the power level of one signal degrades all other signals within the same bandwidth. However, reducing TLP too far results in undesirable SNRs at the receivees 26. To maintain a desired SNR at the minimum transmission power level, adaptive power control is used. Typically, a transmitter 24 will send a signal to a particular receiver 26. Upon reception, the SNR is determined. The determined SNR is compared to a desired SNR. Based on the comparison, a signal is sent in the reverse link to the transmitter 24, either increasing or decreasing transmit power. This is known as forward channel power control. Conversely, power control from the subscriber unit 22, to the base station 20, is known as reverse channel power control. Amplifiers 641, 642... 64n are used for adaptive power control in Figure 3. The amplifiers 641, 642 ... 64n are coupled to the inputs of the combiner 34 to individually control each signal's power level. Figure 4a. 4b, 4c and 4d show a simplified illustration of three spread spectrum signals 421, 422, 423 and a resultant combined signal 44. Although each signal 421, 422, 423 is spread with a different pseudo random chip code sequence, each signal 421, 422, 423 is synchronous at the chipping rate. When the individual chips within the sequences are summed, the combined signal may have extreme transients 46, 48 where the chip energies combine or low transients 47 where they subtract. High transient peaks arc undesirable. For every 3 dB peak increase, twice the base amplification power in Watts is required. Not only does the transient burden the amplifier, but the power sourcing the amplifier must have a capacity greater than the maximum transient that may be expected. This is particularly undesirable in hand-held battery operated devices. Additionally, to design for higher power levels resulting from high transients, more complex amplifier circuitry is required or compromises between amplifier gain, battery life and communication time result. High valued transients force the amplifier 38 into the nonlinear region of its dynamic range resulting in increased out-of-band emissions and reduced amplifier efficiency. Accordingly, there exists a need for an adaptive RF transmitter system that addresses the problems associated with the prior art. SUMMARY OF THE INVENTION The invention reduces transient peaks in signals transmitted in CDMA communication systems. A plurality of spread spectrum data signals are combined into a combined signal having fluctuating power level corresponding to the combination of the data signals. The combined signal is modulated to produce an RF signal for transmission. The average power of the combined signal is measured over a selected time period. The combined signal power level is adaptively limited to a calculated power level based at least in pan on the measured power. BRIEF DESCRIPTION OF THE DRAWINGS Figure I is an illustration of a prior art CDMA system. Figure 2 is an illustration of a prior art CDMA transmitter and receiver. Figure 3 is a system block diagram of a prior art transmitter. Figure 4a is an illustration of a first pseudo random chip code sequence. Figure 4b is an illustration of a second pseudo random chip code sequence. Figure 4c is an illustration of a third pseudo random chip code sequence. Figure 4d is an illustration of the combined chip code sequences of Figures 4a - 4c. Figure 5 is a system block diagram of an embodiment of the invention with the power measurement device coupled to the amplifier. Figure 6 is a system block diagram of an alternate embodiment of the invention with the power measurement device coupled to the modulation. Figure V is an illustration of the probability distribution function of the power levels of a combined signal. Figure 8 is a plot of the loss in the received signal to noise ratio versus the clipping level. Figure 9 is a plot of the loss in the received signal to noise ratio versus the clipping level in a CDMA communication system using adaptive power control. Figure 10 is a system block diagram of an alternate embodiment of the invention with the processor controlling the amplifier gain. DESCRPPTION OF THE PREFERRDD EMBODIMENTS The preferred embodiments will be described with reference to the drawing figures where like numerals represent like elements throughout. Figures 5 and 6 depict transmitter systems of the invention. A group of data signals 281, 282... 28N that include traffic, pilot and maintenance signals are mixed with different chip code sequences 321, 322... 32N and are summed together in a combiner 34 as a combined signal 44. The combiner 34 is coupled to an adjustable signal limiter 50 (clipper) where signal power levels are hard limited to +B and -B dB. Power levels in between +B and -B are not affected. The limited signal 45 is modulated up to RF by a mixer 36. The modulated signal is amplified by an amplifier 38 to a predetermined power level and radiated by antenna 40. Figure 7 illustrates a typical probability distribution function of the combined signal power level. A combined chip 46, 47, 48 as shown in Figure 4d will have an associated power level. The probability of a given combined chip having a particular power level is shown in Figure 7. The two extreme power levels are +K and -K As shown in Figure 7. the probability of a given combined chip having a power level of+K or -K is extremely low. Whereas, the probability of a combined chip having a power level in the middle of the two extremes is high. Since a spread spectrum signal is spread across a wide communication bandwidth and there is a low probability that a combined chip will have a power level at the ends of the distribution, the combined signal 44 can be clipped below these extremes with insignificant loss. The transmitter system adjusts the clipping levels, P, to eliminate the signal transients with only a small decrease in the transmittal signal-to-noise ratio (SNR). . Figure 8 is a graph illustrating the relationship between SNR and clipping levels for a system not using adaptive power control. The solid line, dash line and dotted line depict communication channels with different operating SNRs. As shown in Figure 8, for a P set at a clipping level of two standard deviations the loss in SNR is negligible and at a clipping level of one standard deviation the loss is only approximately 0.2 dB. For a system using adaptive power control, Figure 9 is a graph of SNR versus the clipping level. The results are similar to those obtained in a system not using adaptive power control. As shown in Figure 9, with a clipping level of two standard deviations, the loss in SNR is again negligible. Accordingly, the clipping circuitry is applicable to systems utilizing adaptive power control and systems not using adaptive power control. Referring back to Figure 5, to determine B, the invention uses a power measurement device 52 and a processor 54. The power measurement device 52 is coupled to either the output of the RF amplifier 38 as shown in Figure 5 or the mixer 36 as shown in Figure 6. Preferably, the power measurement device 52 determines the average of the square of the magnitude of the transmitted signal over a predetermined time period. The output of the preferred power measurement device 52 approximates the variance of the mixed signal 49 or the signal 51 being transmitted. Alternatively, the power measurement device 52 determines an approximation of the standard deviation by taking the average of the absolute value of the signal 49, 51 or the power measurement device 52 measures the magnitude of the signal 49, 51 with the processor determining either the variance or standard deviation. The output of the power measurement device 52 is coupled to a processor 54. If the power measurement device 52 is coupled to the output of the amplifier 38, the processor 54 scales down the output of the power measurement device 52 by the gain of the amplifier38. The processor 54 determines the proper clipping level for B. Depending on the desired SNR and bandwidth, the value for B will be a multiple of the standard deviation. If the power measurement device 52 approximates the variance, the processor 54 will take the square root of the devices output as the standard deviation. In the preferred embodiment, B will be two times the standard deviation. In certain situations, the processor 54 overrides the determined value of p. For instance, if the transmitter 25 was used in a base station 201, 202... 20N, a large increase in the number of users may result in B being temporarily set too low. This will result in an undesirable received SNR. As supplied to the processor 54 through the line 60, the number of users currently in communication with the base station 201, 202... 20N, is used to either change B or temporarily disable the clipper 50 to allow all signals to pass unaltered when appropriate. Additionally, since the probability distribution function assumes a large sample size. a small number of users may result in an undesired received SNR. Accordingly, if only a few users were in communication with the base station 201, 202... 20N, the clipper 50 may be disabled. In addition, when there are only a small number of users active, the amplifier's dynamic range is not reached. Accordingly, there is no need to clip the combined signal. Under other situations, it may be necessary to override the clipper 50. For instance, in some COMA systems short codes arc used during initial power ramp up. Since these codes are not long enough to approximate a random signal, by chance one code may result in a large number of high transient peaks within the signal. Clipping these transmissions may dramatically decrease the received SNR and unnecessarily delay the initial power ramp up procedure. In these situations, a signal will be sent to the processor 54 through the line 62 to override the clipper 50. In an alternate embodiment shown in Figure 10, the processor 54 is also used to control the gain of the amplifier 38 through the line 58. Stored in the processor is the amplifier gain characteristic. The amplifier gain is adjusted to keep the amplifier from going into the nonlinear operating region. Accordingly, out-or-band emissions and interference to services in adjoining frequency bands is reduced. Although the invention has been described in part by making detailed reference to certain specific embodiments, such detail is intended to be instructive rather that restrictive. It will be appreciated by those skilled in the art that many variations may be made in the structure and mode of operation without departing from the scope of the invention as disclosed in the teachings herein. 1. A transmitter for use in a CDMA communication system station, the transmitter comprising: means for combining a plurality of spread spectrum data signals into a combined signal having a fluctuating power level corresponding to the combination of the data signals; means for modulating the combined signal to produce an RF signal for transmission; means for measuring average power of the combined signal over a selected time period; and means for adaptively limiting the combined signal power to a calculated power level based at least in part on said measured power. 2. The transmitter of claim I wherein said measuring means measures an average power of the RF signal over the selected time period. 3. The transmitter of claim 1 further comprising an amplifier for amplifying the RF signal prior to transmission; wherein said measuring means measures an average power of the amplified RF signal over the selected time period. 4. The transmitter of claim I wherein said measuring means determines a variance of the combined signal power wherein said adaptively limiting means limits the combined signal power to the calculated power level based in part on the approximation of the variance. 5. The transmitter of claim I wherein said measuring means determines an average of a square of the combined signal power; wherein said adaptively limiting means limits the combined signal power to the calculated power level based in part on the average of the square. 6. The transmitter of claim 1 wherein said measuring means determines an average of an absolute value of the combined signal power; wherein said adaptively limiting means limits the combined signal power to the calculated power level based in part on the average of the absolute value. 7. The transmitter of claim 1 wherein said measuring means determines a magnitude of the combined signal power and said measuring means having processing means for determining a variance of the combined signal power based on the determined magnitude; wherein said adaptively limiting means limits the combined signal power to the calculated power level based in part on the determined variance. 8. The transmitter of claim 1 wherein said measuring means having: processing means for determining a standard deviation of the combined signal power and said adaptively limiting means limits the combined signal power to the calculated power level based in part on the determined standard deviation. 9. The transmitter of claim 8 wherein the calculated power level is two of the determined standard deviations. 10. The transmitter of claim 8 wherein the calculated power level is the determined standard deviation. 11. The transmitter of claim 8 wherein said processing means disables said adaptively limiting means in response to a number of active users. 12. The transmitter of claim 8 wherein said processing means disables said adaptively limiting means during transmission of short codes. 13. The transmitter of claim 8 further comprising an amplifier for amplifying the RF signal prior to transmission and processing means for determining the calculated power level; wherein a gain of said amplifier is adjusted by said processing means in response to the calculated power level and stored gain characteristics of said amplifier. 14. A method for transmission in a CDMA communication system, the method comprising: combining a plurality of spread spectrum data signals into a combined signal having a fluctuating power level corresponding to the combination of the data signals; modulating the combined signal to produce an RF signal; measuring average power of the combined signal over a selected time period; adaptively limited the combined signal power to a calculated power level based at least in part on said measured power; and transmitting the RF signal. 15. The method of claim 14 wherein the measuring is of an average power of the RF signal over a selected time period. 16. The method of claim 14 further comprising amplifying the RF signal prior to transmission; wherein the measuring is of an average power of the amplified RF signal over the selected time period. 17. The method of claim 14 wherein the calculated power is based on a variance of the combined signal. 18. The method of claim 14 wherein the calculated power is based on standard deviation of the combined signal. 19. The method of claim 18 wherein the calculated power is one of the standard deviations. 20. The method of claim 18 wherein the calculated power is two of the standard deviations. 21. The method of claim 14 wherein the step of adaptively limiting is not performed in response to a number of active users. 22. The method of claim 14 wherein the step of adaptively limiting is not performed in response a transmission of short codes. 23. The method of claim 14 further comprising: amplifying by an amplifier the RF signal by a gain factor prior to transmission; and adjusting the gain factor in response to the calculated power level and stored gain characteristics of the amplifier.

Documents:

IN-PCT-2002-00249-KOL-(03-01-2005) EXAMINATION REPORT REPLY RECIVED.pdf

IN-PCT-2002-00249-KOL-(20-02-2002) ABSTRACT.pdf

IN-PCT-2002-00249-KOL-(20-02-2002) CLAIMS.pdf

IN-PCT-2002-00249-KOL-(20-02-2002) CORRESPONDENCE.pdf

IN-PCT-2002-00249-KOL-(20-02-2002) DESCRIPTION COMPLETE.pdf

IN-PCT-2002-00249-KOL-(20-02-2002) DRAWINGS.pdf

IN-PCT-2002-00249-KOL-(20-02-2002) FORM 2.pdf

IN-PCT-2002-00249-KOL-(20-02-2002) FORM 3.pdf

IN-PCT-2002-00249-KOL-(20-02-2002) FORM 5.pdf

IN-PCT-2002-00249-KOL-(20-02-2002) FORM-18.pdf

IN-PCT-2002-00249-KOL-(20-02-2002) INTERNATIONAL PUBLICATION.pdf

IN-PCT-2002-00249-KOL-(20-02-2002) OFFICE DOCUMENT.pdf

IN-PCT-2002-00249-KOL-(20-02-2002) PA.pdf

IN-PCT-2002-00249-KOL-(20-02-2002) PCT SEARCH REPORT & OTHERS.pdf

IN-PCT-2002-00249-KOL-(20-02-2002) PRIORITY DOCUMENT.pdf

IN-PCT-2002-00249-KOL-(20-02-2002) SPECIFICATION.pdf

IN-PCT-2002-00249-KOL-(24-01-2004) FER.pdf